FR2784284A1 - New dental implant with mesenchymal cells grown on its root giving it more realistic characteristics - Google Patents

Abstract

Dental implant made by immersing a root made of inert material in a culture of undifferentiated mesenchymal cells (22), is new. The medium (21) available to the cells contains specific growth cultures which allow the cells to differentiate into cementoblasts or fibroblasts. An Independent claim also included for a device where cells can be grown on the implant. Cells and culture medium are held in a culture container separated by a porous wall (20). The root is agitated side to side or rotated every 1 to 60 seconds by 0.005 to 2 mm, stimulating cell growth on the root. This is done mechanically, hydraulically or magnetically.

Description

 The present invention relates to periodontal-integrated dental implants, comprising cement on the surface of the root and a ligament for connecting the cement to the bone socket, like a natural tooth.

 The invention relates to a method for preparing this implant by bringing the implant into contact with undifferentiated progenitor mesenchymal cells under culture conditions allowing adhesion of cementoblasts and the alveolo-dental ligament on the root part of the implant. implant and implantation of the implant carrying differentiated tissue cells.

 The invention also relates to a cell culture device for the preparation of a dental implant. Finally, it relates to a method of replacing lost or compromised teeth with implants to which are affixed by an appropriate cell culture technique, the cells and biological tissues then making it possible to obtain healing in the mouth by cement and ligaments between the bone alveoli. and the implanted roots.

 Dental transplants and reimplants have been practiced for several decades and many techniques have been described.

Among the techniques using implantation, those which are mainly practiced today are the following:
a) Prostheses on integrated osteo implants which are artificial titanium roots which are stabilized by bone ankylosis. The masticatory force is transmitted to the bone without any cushioning, due to the absence of the alveolo-dental ligament which is an important factor in protecting the teeth against impacts, overloads and the risks of fracture.
b) Transplants or other dental grafts, which do not have the drawbacks of the previous approaches but require the extraction of an available and generally non-functional donor tooth.

 Prior to the description of the present invention, a reminder of the physiological conditions of the connection of the natural tooth is necessary. The tooth is anchored in a cavity called an alveolus, in the alveolar bone. The anchoring between the root and the bone is carried out thanks to a ligament consisting mainly of bundles of collagen fibers anchored on one side in the bone and on the other in the cement, mineralized layer resulting from the differentiation of mesenchymal cells undifferentiated as cementoblasts which produce the organic matrices and minorâtes constituting the cementum. In this cement, collagen fibers are inserted perpendicularly and included parallel to the surface of the cement, forming a network between them.

 An implantation of an artificial tooth, to be functional and accepted, should ideally reproduce anatomically and histologically the support structures of natural teeth, that is to say the cementum, the alveolar-dental ligament, the alveolar bone, with all their components: differentiated or undifferentiated cells, connective fibers and other fibers (elastic, oxytalanes, elauin), the fundamental substance, mineralized tissues, vascularization and innervation.

 The fibroblasts, ligament generators, the cementoblasts and the osteoblasts lining the alveolar bone result from the differentiation of the undifferentiated mesenchymal progenitor cells which usually sit in the connective tissues around the blood vessels.

They can be found on the surface of the roots of extracted teeth and / or in the alveoli of extracted teeth or in the ligaments of a tooth, or in other connective tissues of the mouth or not.

 The invention results from the demonstration that under certain conditions of biological and mechanical stimulation, the natural physiological environment of the root described above can be reconstituted from a culture of undifferentiated mesenchymal progenitor cells.

 The proposed invention therefore makes it possible to replace the teeth lost in a majority of clinical situations, by unalterable artificial teeth connected to the maxillae by the same tissue elements as the natural teeth, ie a cement, an alveolodentary ligament, and a alveolar bone and allowing normal attachment of the gum to the implant collar. These four elements are the constituents of the periodontium, which can subsequently ensure its normal physiological role, namely absorbing the constraints of chewing, avoiding overloads, adapting the position and mobility of the tooth to the average load it receives. .

The present invention provides a method of manufacturing a dental implant comprising:
-the preparation of an implant composed of a root part and a coronary part and made of a biocompatible material in a shape adapted to an extracted tooth;
-The immersion of the root part of this implant in a culture of undifferentiated progenitor mesenchymal cells, in a culture medium whose composition allows differentiation into cementoblasts and fibroblasts, for a period sufficient for this differentiation and for the adhesion of cementoblasts on the root part and in the formation of a first layer of cement and a blank of alveolo-dental ligament attached to this cement;
-the collection of the implant carrying the differentiated tissues affixed on its root part.

 The choice of implant is guided by different criteria. The first criterion is its morphology. This will depend on the volume of the dentin (ivory) of the tooth to be replaced, i.e. the total volume minus the enamel and cementum. The desired shape is obtained for example by comparison with the extracted tooth; it would then be cut on demand, to the exact shapes of the tooth to be replaced. The desired shape can also be obtained by radiological, computed tomography or equivalent data. The implant is then cut from a block made of a chosen material, by a numerically controlled machine, or by any other means. A number of typical forms can also satisfy a majority of cases; they will have roots of varying lengths, diameters, conicities, round or oval sections.

 The choice of implant material in the method of the invention is guided on the one hand by the biological and immunological acceptability of said material in the mouth, and on the other hand on its performance as a support for the adhesiveness of the cementoblasts. The material of the implants must be biocompatible, and mechanically strong enough to avoid the risks of fractures; it must also be frosted on the surface in order to facilitate adhesion of the cells, and finally, it must be close to the color of the natural tooth. Known materials can be considered in the choice of implant material, for example titanium, alloys or ceramics, for example Zirconia. It may possibly be envisaged to use devitalized natural teeth obtained from any source whatsoever. The description of such materials is described in Periodontology 2000 (1998) 17: 7-21.

 The dental implant used in the method of the invention comprises, in addition to the root part which is brought into contact with the undifferentiated mesenchymal culture, a coronary part capable of being capped by a crown of resin, composite, metal alloy or ceramic . Grooves are provided in the coronary part of the implant to stabilize the suture threads which hold the implant in its socket when it is placed in the mouth. In occlusal view of the implant, a groove can for example occupy a diameter and two others cross this diameter at right angles at equal distance from the center and the periphery.

However, these grooves can be arranged otherwise without disturbing the ergonomics of the system as shown in Example 3 below.

 The implant used in the method of the invention may finally comprise a rod coaxial with the tooth and fixed on its coronary part which will facilitate handling and subsequent reimplantation in the mouth.

 One of the essential characteristics of the process of the invention is the formation by in-vitro cell culture, in the presence of the implant, the shape and material of which have been selected according to the criteria described above, of a layer of cells and tissues adhering to the root part of the implant. These cells and tissues exist naturally between the root of the tooth and the alveolar bone; thus, the physiology of reimplantation in the mouth is very similar to natural conditions.

 It is well known that fibroblasts are the dominant cell type of all connective tissues in the human body and are in particular the essential cells of the tissues of the periodontal ligament. The differentiated cells of the periodontium that are the cementoblasts, the fibroblasts and the osteoblasts come from the differentiation of undifferentiated cells that are the progenitor mesenchymal cells.

These cells usually sit in the connective tissue around the blood vessels. They can be removed from the surface of roots of extracted teeth if these are not contaminated and / or in the alveoli of extracted teeth, or in the ligament of a tooth by removal by a needle-trocard or by explants of tissues. oral connectives. These progenitor cells exist in other connective tissues of the body, and can therefore be taken from non-buccal sites.

 The undifferentiated cells thus removed are cultured under conventional conditions, for example in a Petri dish, in Falcon-type culture dishes, or in roller bottles.

The undifferentiated mesenchymal cells collected are cultured in a medium whose composition allows growth and their differentiation into fibroblasts. Such media are conventional culture media for fibroblastic animal cells, as described in, for example, by S. Pitaru et al in J. Périodont Res. (1994), 29: 81-94, Review Article. For example, the DMEM environment (Dulbecco's
Modification of Eagle's MEM) (Dulbecco and Freeman, 1959;
Morton, 1970) supplemented with fetal calf serum can be used.

This medium is supplemented with antibiotics and antifungals. The cells in culture are put in condition of biological stimulation by addition to the medium of molecules or compositions necessary for the development and the differentiation of the cementoblasts and fibroblasts. They may be growth factors, by way of example we may cite:
PDGF, IGF, proteins of the organ of the embryonic enamel, bFGF, and other molecules having an anabolic effect on the periodontium, for example nifedipine, vitamin C, the unsaponifiables of avocado, corn and / or soy, this list is not exhaustive.

 When the cell density reaches 105 cells / ml, the cells are transferred to a culture device allowing the immersion of the root part of the implant to be treated. The appropriate culture device also forms part of the invention and is described below.

 The implant is then positioned in the culture device until a layer of cementoblasts adheres to its root part is obtained and produces a first layer of cement with connective fibers inserted into this cement, and a second layer containing fibroblasts and collagen in formation.

 After 15 to 30 days of immersion in the culture medium included in the device, the implant is then collected and "implanted" in the mouth in the cell under the conditions described in the protocol of Example x below.

 In the process of the invention, the biological stimulation of cell differentiation of undifferentiated mesenchymal cells can be supplemented by "physiological" mechanical stimulation. This is achieved by a periodic force applied to the implant when it is immersed in the cell culture. The agitation can be an alternating movement of periodicity between 5 to 60 seconds without restricting the method to this interval, and of amplitude between 0.01 and 2 mm; the displacement can be horizontal, namely orthogonal to the axis of the implant, vertical, ie longitudinal to the axis of the implant, or a combination of the two. It can also be a rotary movement.

 The movement applied to the implant in its culture medium has a double function, conferred by the relative movement between the implant and the artificial cell materialized by the porous membrane. The first is to create a functional stimulation of cells in culture, which increases their proliferation, their differentiation, their synthesis activities (cement and collagen), and the physiological orientation of the structures in formation. The second function of this agitation is to agitate the cell culture as recommended for any culture of eukaryotic cells; this allows better ventilation of the cells as well as circulation of the medium and its nutrients in the environment of the cells, which promotes their development.

 This agitation can be carried out by any system making it possible to adjust the periodicity and the amplitude in the ranges situated above. It can be a mechanical, electrical, hydraulic, pneumatic system, this list not being exhaustive. Different embodiments can be envisaged in this regard: the movement can be applied only to the implant, by means of a rod itself fixed to the coronary part of the implant; it can also be applied to the entire system containing the cell culture in which the root part of the implant is immersed. Finally, it can be applied to cell culture, the implant as such being fixed to a support by a rod secured to the coronary part. What is sought in this mechanical agitation is the relative movement of the root part of the implant and of the culture medium in which it is immersed, under the conditions of periodicity and amplitude recommended above, and which allow to fulfill the two functions of cellular stimulation and cell agitation.

 The present invention also relates to a cell culture device for the preparation of a dental implant.

More particularly, when reference is made to FIG. 1, the present invention relates to a cell culture device for the preparation of a dental implant (30) consisting of a root part (31) and a part coronary on which is fixed a rod (32) allowing its manipulation and its subsequent mouthing, said device comprising:
a culture dish (10) whose shape includes a longitudinal axis,
said culture dish being closed by a cover (11) and contains a porous wall (20) delimiting a first space (21) containing the cell culture medium, and a second space (22) containing the cells in culture, and in which the root part of the implant is immersed, said wall having a configuration allowing a space of between 0.1 and 5 mm to be created creating an artificial alveolus between the root part of the implant and the wall and ideally 1 mm .

 Said device comprises means for agitating the implant in said artificial socket according to an alternating movement of periodicity between 5 and 60 seconds and of amplitude between 0.01 and 2 mm or according to a rotary movement of periodicity between 5 and 60 seconds. This stirring means can be mechanical, hydraulic or magnetic so as to impart an alternating or rotary movement to the rod.

 The present invention also relates to a dental implant capable of being obtained by a process as described above and which allows the reconstruction on the root surface of the implant of the various constituent tissues of the periodontium, namely the cement and the ligaments connecting cementum to the alveolar bone. This implant or artificial tooth is made of an inert bio-compatible material, in a shape adapted to the extracted tooth.

The dental implant according to the invention will therefore comprise a coronary part and a radicular part, which, before implantation in the mouth, will be covered with differentiated cells then allowing in situ a more complete formation of the cementum and the ligament. A dental implant according to the invention allows in two to three months to ensure the complete reconstruction of a normal periodontium supporting the implant.

 Finally, the invention relates to a method of replacing lost or compromised teeth with artificial implants on which biological tissues are affixed, using an appropriate cell culture technique, which then makes it possible to obtain healing in the mouth with cement and ligament, between the bony alveoli and the implanted roots.

 The exemplary embodiments and the figures below, without being limiting, serve to illustrate the invention and allow the person skilled in the art to carry it out directly, or any functional equivalent allowing the dental implant to be produced, the surface of which the root part is lined with cementoblasts forming a cementum and collagen fibers, and fibroblasts developing collagen fibers reconstituting a sketch of the alveolo-dental ligament.

 FIG. 1 represents a diagram of an organotypic culture device around the artificial roots, with biological and physiological (mechanical) stimulation to obtain cementogenesis and ligamentogenesis and described in detail in Example 2 below.

FIG. 2a represents an arrangement diagram of the occlusal grooves for stabilizing the sutures retaining the implant:
(1) represents the occlusal view,
(2) is a perspective view.

 FIG. 2b represents diagrams showing the coronary part of the implant emerging from the gum; (A): the proximal sutures are not yet united through the mesio-distal groove; (B): the knots are made.

Example 1-Cell culture protocol aimed at creating a periodontium in vitro:
1) Collection of cells:
The target cell population is that of undifferentiated mesenchymal progenitor cells which usually sit in the connective tissues and in the endorsed spaces around the blood vessels.

Direct debits can be:
- by scraping with a sterile scalpel of uncontaminated surfaces of roots of extracted teeth;
-by curettage of alveoli of extracted teeth, also uncontaminated,
-by biopsy of periosteal or supra-periosteal tissue,
-by removing other connective tissue from the mouth or not.

2) Transport of samples:
The tissues are placed in tubes containing a culture medium such as Dulbecco's modification of Eagle's MEM (DMEM) with:
-20% fetal Bovine Serum (FBS),
-streptomycin (100,000 Mg / ml),
-fungizone (1%),
- buffer system, for a maximum duration of 24 hours and at 4 C.

 3) Primary culture.

-The biopsies are reduced with a scalpel to fragments of approximately 1x1x1 mm;
-The explants obtained are placed in 60 mm culture discs containing:
-DMEM,
-20% FBS,
-1% penicillin-streptomycin,
-1% fungizone incubated at 37 C in humidified air at 5%;
-after 3 days, the medium is replaced by DMEM + 10%
FBS, without antibiotics.

4) Subcultures:
When the cell proliferation around the explants is evident, and the cells arrive at confluence, they are detached with 0.05% trypsin in phosphate buffered serum for 10 min, then distributed in other culture dishes.

 -the middle is the same.

 -after 3 or 4 passages, the quantity of fibroblasts obtained is sufficient to seed the root.

5) Membership phase:
In the same medium supplemented with growth factors, the cells are placed around the artificial root in an artificial alveolus leaving only 1/2 mm to 1 mm of space.

 The root and its container are connected by a suitable stopper.

 The assembly is placed horizontally to promote adhesion to the surface of the root, and rotate 120 every 15 mm.

6) Culture phase stimulated in the device:
After three hours, the root is placed vertically in the culture system with physiological stimulation, and with renewal of the medium which growth factors are added.

7) Transport condition:
After 15 days, the device is used to transport the implant ready to be put in place. Depending on the transport time, the system is kept at 37 C or reduced to 4 C.

 The implant filled with cement and ligament is removed from the culture device and immediately placed in the alveolus prepared in advance, then sutured.

Example 2-Realization of a cell culture device:
Figure 1 shows the principle of such a device and the figures in parentheses refer to the various elements of this figure.

The dental implant (30) consists of a radicular part (31) and a coronary part on which a fixing axis (32) allows it to be agitated, manipulated and subsequently placed in the mouth. The device includes:
a culture dish (10), the shape of which comprises a longitudinal axis;
said culture dish is closed by a slightly flexible cover (11) and contains a porous wall (20) delimiting a first space (21) distal relative to the root part (31) containing the cell culture medium, and a second space (22), containing the cells in culture, and in which the root part of the implant is immersed. The wall delimiting the two spaces has a configuration such that the second space (22) is of shape and dimensions such that a space between 0.1 and 5 mm (ideally 1 mm) between the wall (20) and the root part of the implant (31) creates an artificial socket.

 The culture dish (10) can have a circular section or any other shape. Its section must be sufficient to accept the root of the implant, the second space (22) containing the cells in culture and the first space (21) containing the reserve of culture medium. The height of the box (10) is at least 10 mm higher than the total height of the implant, or about 50 mm in height. In the apical part, a space must be reserved for the circulation of the culture medium and the stem must be accessible outside the box provided with its cover (11) by a detachable fixing ring.

The lid (11) of the box must fit onto the latter under conditions making it possible to preserve the sterility of the culture medium; this is done for example with a lid similar to that of a Petri dish. Any other method of fixing the cover (11) to the box (10) can, of course, be envisaged by a person skilled in the art from the moment when the functional characteristics of this device are preserved, namely the immersion of the part root in a cell culture, said culture forming an artificial alveolus of section between 0.1 and 5 mm around the root part of the implant (31)
The cover may include a central part (12) in which the fixing axis (32) of the implant can come to fit together by means of a fixing ring which makes it possible at the time of the positioning of the implant in the mouth to remove it from the culture dish which is also used for transport, in a special thermo-regulated container, protecting from any contamination and stabilized vertically.

 The device according to the invention further comprises, a means of agitating the implant according to an alternating movement of periodicity between 5 and 60 seconds and of amplitude between 0.1 and 2 mm or according to an alternating rotary movement of periodicity between 5 and 60 seconds.

 This agitation has a double function, the usual function of agitation of a cell culture by allowing correct aeration and a good distribution of the culture medium and of its nutrients on the cells in suspension or adherent; the second function is to create a mechanical stimulation which leads to the cellular differentiation sought in cementement cells and fibroblasts which generate ligaments.

This agitation can be imparted in the device in several ways:
the movement can be applied to the implant according to a mechanical, hydraulic or magnetic agitation means applied to the rod (32).

In this case, the cover (11) of the box (10) must be provided in the central position with a means of fixing the rod (32) thus making it possible to give an autonomous movement of the implant within the assembly. box / lid. To this end, the means for fixing the rod in the central position of the cover, or the cover by itself (11) must have sufficient flexibility for carrying out the movement;
the movement can be imparted to the box / lid assembly, being installed as such being fixed on a support by any suitable means; here again, the cover (11), where the means for fixing the rod to the cover must have the flexibility necessary for carrying out the movement.

The culture dish (10) contains two:
a first space (21) contains the culture medium. This may for example be a DMEM type medium supplemented with fetal calf serum and in which the various growth factors or molecules necessary for cell growth and differentiation are added;
a second space (22) contains the cell culture seeded with the preculture of the mesenchymal cells as described above.

 These two spaces are separated by a porous wall or membrane, or a pierced wall stabilizing a microporous membrane, having sufficient rigidity to give it a desired and stable shape.

This wall has a porosity and a shape the characteristics of which are as follows:
a) the porosity is such that the culture medium containing its nutrients and its growth factors diffuses into the second compartment (22), while the cells remain confined in said compartment. The porosity will therefore be between 0.2 and 2 microns.

Any type of material allowing this porosity and the relative rigidity necessary for characteristic b below can be used. Examples of polycarbonate, cellulose acetate (Millipore, Millicell filter), etc.
b) The membrane or its mounting system is fixed to the box (10) at a level higher than the level of the culture medium. It can join the edges of the box (10) in the form of a cone for example. In addition, it creates in the box (10), an artificial socket similar in shape to the shape of the root part of the implant (31) so as to create a space of 0.1 to 5 mm and preferably 1 mm wide between the root of the implant and said porous wall.

 The membrane with its mounting system must be detachable from the bottom of the box while remaining integral with the cover itself connected to the implant. Thus, when the cover is lifted, the first space (21) is completely accessible to modify or change the environment.

 The entire device comprising the box (10)), the cover (11), the wall (20) and the implant (30) is placed in a culture incubator at 37 ° C. containing 95% humidified air and 5 % of CO2.

 Example 3-Biocompatible example, as described in Periodontology 2000 (1998), 17: 7-21.

 With a view to subsequent implantation, grooves are provided in the coronal part of the implant to stabilize the sutures which hold the implant in its socket, during placement in the mouth.

These grooves can be 1 mm wide and 2 mm deep. An example of their arrangement is shown in diagram 2a. This arrangement allows the sutures (1) to be passed as shown in diagram 2b. A thread is passed through quilting points in the vestibular gum (2) and in the lingual gum (3) and passes twice through the occlusal side of the implant in the two vestibulo-lingual grooves (4). It makes it possible to retain the implant but also to adjust the height of the free edge of the gum relative to the implant. A simple suture is placed to bring the distal gingival papillae closer to the implant, its two strands are left after the node at a length of 5 cm. The same operation is carried out in mesial of the implant, leaving strands of 20 cm. Then each strand of mesia! is tied with each distal strand through the mesio-distal groove of the implant. The implant is therefore secured by three sutures. A circular cervical point is often necessary to better bring the gingival rim closer to the periphery of the implant, and to prevent the implant from sinking when it is positioned at the level of a maxillary sinus.

Example 4-Implantation in the mouth:
The dental implant according to the invention is placed in the mouth after approximately 15 days of culture in the device described above.

A dental implantation protocol according to the invention comprises several phases and can be as follows:
a) Prior oral cleansing and use of antiseptic and antibiotic mouthwashes: the oral bacterial load must be reduced as much as possible to avoid contamination of the healing area.
b) Preparation of the socket: the ideal situation is to have extracted the tooth to be replaced around 15 days before. It then suffices to gently curette the alveolus. The partial gingival healing makes it possible to properly "crimp" the implant collar once in place, to obtain satisfactory sealing of the wound at this level and healing by short junction epithelium.

Epithelial cells do not migrate along the root.

 In other cases where the alveolus does not preexist, it should preferably be prepared 15 days in advance after elevation of a muco-periosteal flap.

The cell is prepared by drills of increasing diameters, at slow speed and under irrigation of sterile isotonic serum. The drills are adapted to the standard forms of the standard implants. Some drills work only in their axis, others allow to "train"
The cell adequately by a cutting edge on their lateral faces. They lead to an alveolus always larger than the implant, leaving a spacing of at least one millimeter, so that the bone is not in direct contact with the implant.

In the sinuses, after elevation of a muco-periosteal flap and perforation of the bone wall, the sinus mucosa is pushed back by special lifters. This preparation must imperatively be carried out approximately 15 days before implantation, which makes it possible during implantation to repel the sinus mucosa without the risk of perforating it.
c) Models made of neutral and sterilized material (sterilizable) are produced in the exact shape of the implants, complete crowns included, standard or individualized to result in an ideally placed implant, allowing the preparation of the alveolus to be controlled.

 They include a grip grip in the middle of the vestibular side of their coronary part.

 A second type of model includes the complete volume of the crown and a root of the length to be prepared but of a reduced diameter. It is used after the first drilling to control the positioning and, if necessary, to modify it during the enlargement of the cell.

The implant root may not fully fit in the available bone volume. If it protrudes vertically or horizontally from the bone surface, this does not prevent scarring from taking place, and can even generate a spontaneous increase in bone volume around the root not buried, provided that the surfaces not buried in the bone remain submucosal. The same phenomenon occurs in the sinus.
d) The implant, taken out of its culture dish, held by its rod and the fixing ring, is immediately positioned in the socket, preferably without contact with anything, in particular an instrument, a compress, the oral mucosa, tongue, saliva ...

 It is held in place by stitches caught in the gum on either side of the implant, and slid into the grooves prepared in the emerging "coronary" part.

 Stitches should also seal the gum at the implant collar. Points are maintained for approximately 15 days.

 No other compression, particularly rigid to the other teeth, is used.

The coronary part of the implant, reduced at this stage because it does not have the provisional crown, should not come into contact with the opposing teeth.
e) Temporary crowns: standard temporary crowns can be sealed after 15 days on the implants. They are set to have occlusal contact only in centered relationship or maximum intercuspidation. Their outline and their esthetics can be governed by addition or subtraction of resin by grinding.

Control sessions are indicated to ensure the progressive loading of the implant and to avoid any overload, for two months.
f) Final prostheses on implants can be performed approximately 3 months after placement. Conventional techniques can be used. These implants behave just like natural teeth. The ligament that connects them to the bone absorbs stress, avoids overloading, reduces impact, limits the risk of fracture of the prosthetic crowns and the implants themselves.

Claims (15)

 1. Method of manufacturing a dental implant:  -The preparation of an implant composed of a root part and a coronary part and made of an inert biocompatible material in a shape adapted to an extracted tooth,  -The immersion of the root part of this implant in a culture of undifferentiated mesenchymal cells, in a culture medium whose composition allows differentiation into cementoblasts and fibroblasts, for a period sufficient for this differentiation, to the adhesion of cementoblasts on the root part, the formation of a first layer of cementum and a blank of alveolo-dental ligament attached to this cementum;  -The collection of the implant carrying differentiated tissues affixed on its root part.  2. Method according to claim 1 characterized in that the mesenchymal progenitor cells are taken from connective tissues, and placed in preculture in a Petri dish until a density of 105 cells per ml is obtained, then brought into contact with the root part of the implant in a culture medium and in an appropriate culture device.  3. Method according to claim 2 wherein the differentiation of cells into cementoblasts and fibroblasts is stimulated by the addition in the culture medium of specific growth factors or of any molecules stimulating cell differentiation of mesenchymal cells.  4. The method of claim 1 wherein the culture undergoes physiological stimulation by agitation of the implant in the culture device, said agitation having the effect of stimulating the development of cells and tissues on the inert material.  5. Method according to claim 4 characterized in that the stirring is an alternating movement of periodicity between 5 and 60 seconds and of amplitude between 0.01 and 2 mm, or rotary of periodicity between 5 and 60 seconds.  6. Cell culture device for the preparation of a dental implant (30) consisting of a radicular part (31) and a coronary part on which a rod (32) is fixed, allowing its manipulation and positioning subsequent mouth, said device comprising:  a culture dish (10) whose shape includes a longitudinal axis,  said culture dish being closed by a cover (11) and contains a porous wall (20) delimiting a first space (21) containing the cell culture medium, and a second space (22) containing the cells in culture, and wherein the root part of the implant is immersed, said wall having a configuration allowing a space of between 0.1 and 5 mm to be created creating an artificial alveolus between the root part of the implant and the wall.  7. Device according to claim 6 wherein the cover (11) comprises in the central position a means for fixing the rod (32) integral with the implant.  8. Device according to claim 6 or 7 further comprising means for agitating the implant in said artificial socket according to an alternating movement of periodicity between 5 and 60 seconds and amplitude between 0.01 and 2 mm or according to a rotary movement with a periodicity between 5 and 60 seconds.  9. Device according to claim 8 wherein the stirring means is mechanical, hydraulic or magnetic and gives an alternating or rotary movement to the rod (32).  10. Device according to claim 8 wherein the cover (11) is slightly flexible to allow reciprocating movement.  11. Device according to claim 8 wherein the stirring means is imparted by an alternating or rotary movement of the box (10).  12. Device according to one of claims 6 to 11 wherein the porous wall (20) has a porosity between 0.2 and 2 microns.  13. Device according to claim 12 wherein the wall (20) is fixed to the box (10) above the level of the cell culture medium.  14. A dental implant capable of being obtained by a method according to any one of claims 1 to 5, consisting of an inert biocompatible material in a shape adapted to an extracted tooth, the surface of the root part (31) of which is lined with cementoblasts forming a cementum and collagen fibers, and fibroblasts developing collagen fibers reconstituting an outline of alveolo-dental ligament.  15. The implant of claim 13 on which grooves are arranged on its coronary part to stabilize the suture son which hold the implant in its socket when it is placed in the mouth.